Abstract
Deep learning (DL) models are highly research-oriented field in image compressive sensing in the recent studies. In compressive sensing theory, a signal is efficiently reconstructed from very small and limited number of measurements. Block-based compressive sensing is most promising and lenient compressive sensing (CS) approach mostly used to process large-sized videos and images: exploit low computational complexity and requires less memory. In block-based compressive sensing, a number of deep models are needed to train with each corresponding to different sampling rate. Compressive sensing performance is highly degraded through allocating low sampling rates to various blocks within same image or video frames. In this work, we proposed multi-rate method using deep neural networks for block-based compressive sensing of magnetic resonance images with performance that greatly outperforms existing state-of-the-art methods. The proposed approach is capable in smart allocation of exclusive sampling rate for each block within image, based on the image information and removing blocking artifacts in reconstructed MRI images. Each image block is separately sampled and reconstructed with different sampling rate and reassembled into a single image based on inter-correlation between blocks, to remove blocking artifacts. The proposed method surpasses the current state-of-the-arts in terms of reconstruction speed, reconstruction error, low computational complexity, and certain evaluation metrics such as peak signal-to-noise ratio (PSNR), structural similarity (SSIM), feature similarity (FSIM), and relative l2-norm error (RLNE).
Highlights
Medical imaging plays a key role in diagnosis process and considered a most research-oriented field in clinical set-up
We used MATLAB 2015a simulation platform with 3.10 GHz Intel core i5 2400 CPU and 8 GB RAM to perform multiple experiments utilizing the proposed trained model for the reconstruction of MRI images and a brief comparison is made with the state-of-the-arts
To evaluate and validate the effectiveness of the multi-rate deep learning approach, a comparison is made with SparseMRI [50], ISTA-Net [19], FCSA [51], FISTA [52], DR2-Net [53], and BM3D-MRI [54] in terms of peak signal-to-noise ratio (PSNR), structural similarity (SSIM), feature similarity (FSIM), and relative l2-norm error (RLNE) evaluation metrics
Summary
Medical imaging plays a key role in diagnosis process and considered a most research-oriented field in clinical set-up. Medical resonance imaging is an important imaging modality offers better resolution with clear contrast to reveal the inside anatomy. Magnetic resonance imaging has been applied for the diagnosis of many diseases and considered non-invasive, having higher soft-tissue contrast. MRI is slow imaging modality and due to other limitations of scanning system and Nyquist sampling formula, MRI scanners take long time in acquiring k-space data and diagnosing diseases [1]. The main aim is to accelerate the sampling speed and eliminating the artifacts. Under sampling data in k-space are a possible way to accelerate the acquisition process; under-sampling process in k-space violates the Nyquist–Shannon formula which in result generates aliasing artifacts in the resultant image. The main challenge associated with the above discussed limitation is to find out an appropriate algorithm that is able to reconstruct fully uncorrupted image considering the undersampling regime and prior information of image
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